HEALTHWATCH LTD. Patent applications |
Patent application number | Title | Published |
20160128594 | WEARABLE FETAL MONITORING SYSTEM HAVING TEXTILE ELECTRODES - A seamless, smart fetal monitoring garment and methods of using thereof. The system includes a knitted or interwoven garment having a multiplicity of conductive textile electrodes for sensing maternal and fetal electrical vital signals. The maternal and fetal electrical vital signals are selected from a group including maternal heart rate, fetal heart rate and electromyogram (EMG) activities including uterine activities. The method includes wearing the garment, acquiring electrical mixed common, maternal and fetal vital signals from surface region of a pregnant woman, using the plurality of textile electrodes, optimally weighted summing-up the acquired signals, analyzing the summed-up signals to thereby extract the maternal signal and the fetal signal, including determining their heart rates, and including detecting health hazards and in some embodiments, including detecting a uterine contraction sequence suggesting the need to be hospitalized for birth giving. | 05-12-2016 |
20160113581 | DOCKING STATION FOR SMART GARMENTS - A monitoring system for monitoring physiological parameters of a living being. The monitoring system includes a smart garment, a processing unit and a docking station. The docking station enables quick and easy engagement/disengagement of the processor. The docking station is electrically connected to sensors of the smart garment to thereby provide the sensed data to the processor that is docked thereon. The processor is adapted to obtain some or all of the sensed data via a communication interface such as HDMI. The docking station and the smart garment may be interconnected using complementary conductive snap buttons. The docking station may include at least one through opening formed in its back wall, to thereby enable wired operational communication between the processing unit and a respective additional external sensor. The docking station may include a defibrillator protection device to protect the monitoring system from an electric current or voltage surge. | 04-28-2016 |
20160002834 | METHOD FOR LIMITING ELASTICITY OF SELECTED REGIONS IN KNITTED FABRICS - A method for substantially reducing the elasticity of at least one selected textile region of a garment. The method includes producing the garment including a conductive textile electrode and rigidifying the at least one selected textile region. The rigidifying process includes applying rigidifying matter onto or into the at least one selected textile region. The at least one selected textile region is selected from the group consisting of a conductive textile electrode and a region of the garment situated between two adjacent textile electrodes. The invention further provides a garment having a tubular form, knitted by a seamless knitting machine with base-yarns. The garment includes at least one conductive textile electrode, composed of multiple knitted line segments, each knitted with a conductive yarn and a spandex yarn, wherein the spandex yarn and at least one base-yarn are knitted continuously. | 01-07-2016 |
20150305676 | VERTICAL CONDUCTIVE TEXTILE TRACES AND METHODS OF KNITTING THEREOF - A method for knitting a garment having a tubular form, including knitting at least one vertical conductive textile trace on a machine having N participating feeders and M needles. The method includes the steps of continuously knitting the tubular form with one or more flexible non-conductive base yarns, and knitting the vertical conductive textile trace integrally within the tubular form, using a conductive yarn, in addition to spandex yarns, but not the base yarns. The conductive yarn is knitted in a float-loop form by knitting a stitch and skipping over y needles, as follows: repeatably knitting a line segment L | 10-29-2015 |
20150297135 | FLOAT LOOP TEXTILE ELECTRODES AND METHODS OF KNITTING THEREOF - A method for knitting a garment having a tubular form, including knitting at least one conductive textile electrode on a machine having N participating feeders and M needles. The method includes the steps of continuously knitting the tubular form with one or more flexible non-conductive yarns, and knitting the electrode integrally within the tubular form, using a conductive yarn, in addition to the non-conductive yarns. The conductive yarn is knitted in a float-loop form by knitting a stitch and skipping over y needles, as follows: repeatably knitting a line segment L | 10-22-2015 |
20140206948 | INDEPENDENT NON-INTERFERING WEARABLE HEALTH MONITORING AND ALERT SYSTEM - A seamless, substantially continuous, independent and wearable health monitoring and self-alert system, configured for use by a living being on a daily basis, including by a healthy living being. The wearable health monitoring and self-alert system includes a garment worn by the living being adjacently to preconfigured portions of the body of the living being. The system further includes a garment-control device that includes a garment-processor and a battery. The system further includes a multi-lead ECG measuring device including multiple electrodes or probe-devices embedded into the garment, and an alerting unit. Preferably, the system further includes multiple sensing devices selected from the group consisting of sensors and electrodes. At least one of the sensing devices is embedded into the garment, wherein each of the sensing devices is configured to detect a predetermined physiological or chemical parameter of the living being. | 07-24-2014 |
20120209088 | CONTINUOUS NON-INTERFERING HEALTH MONITORING AND ALERT SYSTEM - A seamless and preferably substantially continuous health monitoring system, designed for use by a healthy living being but also suitable for non-healthy living being, the system including a control module, a communication unit and one or more sensors. The sensors can be in-vivo nano-sensors, micro-sensors, subcutaneous, wearable or implanted sensors. The control unit includes an analysis subsystem having a processing unit and an alerting unit. Each of the sensors is configured to detect a predetermined physiological or chemical parameter of the living being. The communication unit is facilitated to transmit the detected parameters to the analysis subsystem. The processor analyzes the detected parameters to thereby determine if the health state of the monitored living being is abnormal. When at least one detected parameter or the health state is determined to be abnormal, the alerting unit is operatively activated to alert a predetermined alert receiving entity. | 08-16-2012 |